BRPI0718820A2 - STEREOSCOPIC IMAGE PROJECTION SYSTEM USING CIRCULAR POLARIZATION FILTER MODULE - Google Patents

Description

STEREOSCOPIC IMAGE PROJECTION SYSTEM USING CIRCULAR POLARIZATION FILTER MODULE

TECHNICAL FIELD

The present invention relates to a stereoscopic image projection system, and more specifically to a stereoscopic image projection system using a circular polarization filter module according to a single projector circular polarization method.

TECHNICAL BACKGROUNDS

A general method for implementing stereoscopic images (or 3D images) is to emit different images to two human eyes. Stereoscopic displays are mainly divided into stereoscopic spectacle displays and stereoscopic (naked eye) displays according to whether or not it is necessary for the viewer to wear spectacles to emit different images to their two eyes respectively.

Particularly, the projection of stereoscopic images that is implemented across a large screen like in a cinema typically utilizes a polarization method in which left and right images pass separately through polarization glasses having left and right polarization lenses, with orthogonal polarization directions. This method implements stereoscopic image projection as follows. Firstly, images are captured using two cameras. The images receive orthogonal polarization directions through polarizers and their overlapping images are then displayed on a screen. Then the viewer views the captured images using both cameras with both eyes through polarizing glasses.

Figure 1 illustrates the structure of a conventional dual projector system for stereoscopic image projection.

To provide stereoscopic image projection according to the polarization method, the conventional dual projector system utilizes two conventional two-dimensional (2D) projectors 1 and 2. One of the 2D projectors 1 gives images on the left and the other 2 2D projector gives images to the left. right. The left and right images are then projected onto a screen 5 after passing through bias filters 3 and 4 with orthogonal bias directions. The overlapping left and right images on screen 5 are then viewed separately by the viewer's two eyes through the left and right image lenses 7 and 8 of the spectator's polarization glasses 6, so that the viewer has the feeling of seeing 3D images.

The conventional dual projector stereoscopic image projection system is very expensive as it utilizes two 2D image projectors and two polarization plates as described above and also includes peripheral devices. The number of projectors required to project stereoscopic films in a movie theater is twice the number of films since two projectors are required for each movie. The positions of the left and right images projected on the screen vary depending on the positions of the two projectors. Therefore, incorrectly adjusting the positions of the two projectors reduces the matching of stereoscopic images.

Thus, there has been a need to provide a single projector system for stereoscopic image projection. Systems based on a method of dividing the LCD module area of a single projector and a method of using an LCD shutter were developed to meet the need.

Figure 2 illustrates the structure of the conventional system for stereoscopic image projection based on the method of dividing the LCD module.

The conventional stereoscopic image projection system shown in Figure 2 operates as follows. First, the Iuz generated by a source of Iuz

201 is reflected using a reflection mirror 202. The reflected light passes through an LCD module 203, which then emits left and right images with different polarization directions. The left and right images are projected on a 205 screen through a condensing lens 204. The left and right images projected on the 205 screen are separated by passing through the left and right image lenses 206a and 206b of the glasses. of polarization 206 used by the viewer, respectively, so that the viewer feels as if he sees 3D images.

The following is a detailed description of how the left and right images are caused to have different polarization directions as the light passes through the LCD module 203.

LCD module 203 includes two polarization films 209 and 210. Each of the polarization films 209 and 210 includes pairs of two regions with orthogonal polarization directions which are arranged alternately in a vertical direction. Specifically, bias film 209 includes pairs of two regions, first bias regions 209a, and second bias regions 209b, and bias film 210 includes pairs of two regions, third bias regions 210a and fourth bias regions 210b. A beam displaying images on the left included in the light reflected by the reflection mirror

202 passes through the first polarization regions 209a of one of the polarization films 209 included in the LCD module 203, while a beam displaying trailing images included in the light reflected by the reflection mirror 202 passes through the second polarization regions 209b of the same film. 209, which has a phase other than 90 degrees with the first polarization regions 209a, so that the reflected beams displaying left and right images have orthogonal polarization directions. Then, when the liquid crystal is triggered according to whether or not each image should be displayed, the images emitted on the left pass through the third bias regions 210a included in the other bias film 210, which has a difference of 90 degree phase with the first polarization regions 209a, while the images emitted on the right pass through the fourth polarization regions 210b included in the other polarization film 210, which has a phase difference of 90 degrees with the second polarization regions 2109a. polarization 209b, so the left and right images have orthogonal polarization directions. The left and right image beams are then projected on screen 205 after passing through the condenser lenses 204. As a result, the left and right images with orthogonal bias directions are arranged alternately on screen 205. The viewer recognizes separately left and right images through the polarizing glasses 206.

The method of projecting stereoscopic images by dividing the area of the LCD module 203 has a problem where the total resolution is reduced since the projected area is divided into projected left image regions and projected right image regions. That is, as the total area of each of the left and right images projected on the screen decreases, the resolution of each image that has passed through each lens of the polarizing glasses should be reduced, which limits its application. to theaters with big screens.

In addition, the left and right images must pass correctly through their defined regions. Otherwise, the stereoscopic image quality will be reduced. This problem is difficult to avoid when left and right images are rendered separately in space. When stereoscopic images are projected on a large screen like in a movie theater, adjusting the positions of the projected left and right images on the screen is not easy as the slight mismatch of positions on the projector will significantly reduce the correspondence of stereoscopic images on the projector. viewer.

Figure 3 illustrates the structure of an LCD shutter-based system for stereoscopic image projection.

To overcome the problem that can occur when the left and right images are spatially divided in the single projector method, the method shown in Figure 3 produces stereoscopic image content including alternating left and right images. A 302 LCD shutter is used to make the left and right images have different polarization directions.

Specifically, in the method of Figure 3, the left and right images are stored alternately in the content. When a 301 projector outputs images according to content, the 302 LCD shutter is triggered to have the same polarization direction as that of the images on the left when the 301 projector outputs images on the left and is triggered to have an image direction. polarization different from those of the images on the left when the projector 301 outputs the images on the right. This operation can be performed by a shutter release 303 which operates the shutter release 302.

5 However, this stereoscopic image projection system using the

LCD shutter has an issue where the shutter response delay when it is triggered causes interference between the left and right images. Especially, the time during which the alternating left and right images are switched should be short enough not to be perceived by a human being. Slow LCD shutter response time will be a serious problem when the left and right images are quickly switched.

In addition, there is a need to provide a technology for replacing the LCD shutter with different means to increase the polarization ratio, since the polarization ratio of the left and right images of the LCD shutter is not so high.

REVELATION

TECHNICAL PROBLEM

An object of the present invention designed to solve the problem is to provide a stereoscopic image projector system, a stereoscopic image projection apparatus and a stereoscopic image projection system including the stereoscopic image projector system and apparatus, wherein single-projector stereoscopic image projection is implemented using a circular polarization filter module so that the number of projectors required for stereoscopic image projection is reduced and the left and right images are also divided in time so as not to cause interference between the images.

Another object of the present invention designed to solve the problem is that of

provide a system that utilizes a rotating circular polarization filter module to selectively polarize the left and right images, wherein the synchronization of rotation of the circular polarization filter module is controlled by considering the left and right image sizes thereby achieving superior quality stereoscopic image projection.

TECHNICAL SOLUTION

One embodiment of the present invention to achieve the above objectives provides a stereoscopic image projector system for a stereoscopic image projection system using a polarization method, the stereoscopic image projector system including a projector to sequentially output left images. It's on the right; a circular polarization filter module including a left image polarization filter and a right image polarization filter; and a filter trigger for rotating and driving the circular polarization filter module according to timing timing of the left and right image emissions of the projector.

In such an embodiment, the stereoscopic image projector system may further include a synchronizer for acquiring timing synchronization of the left and right images of the projector and providing timing synchronization to the filter driver and a frame for fixing and adjusting positions. projector and circular polarization filter module.

The frame can control the positions of the projector and circular polarization filter module to control two-dimensional (2D) or three-dimensional (3D) image projection. Preferably, the circular polarization filter module further includes a light protection region at a boundary between the left image polarization filter and the right image polarization filter.

The projector can receive stereoscopic image content, including left and right images sequentially stored in the stereoscopic image content, and continuously output the content. By rotating the circular polarization filter module, the circular polarization filter module can be controlled such that the left image polarization filter is located in a projector emission aperture when the projector emits left images and the Right image polarization filter is located in the projector's emission aperture when the projector outputs images on the right.

The circular polarization filter module may further include a sensor to detect whether or not the left image polarization filter is located in the projector's emission aperture when the projector emits images on the left and whether the right image polarization filter is or is not located in the projector's emission aperture when the projector outputs images on the right. In this case, a sensor position is preferably determined by considering the size of the left and right images emitted by the projector. In a preferred embodiment of the invention, the circular polarization filter module may further include means for measuring the size of a left image and a right image emitted by the projector; and the position determination means for determining the position of the sensor according to the measurement medium measurement.

Another embodiment of the invention provides a polarization-based stereoscopic image projection system utilizing a projector to sequentially output left and right images, the stereoscopic image projection system including a circular polarization filter module including an image polarization filter on the left and an image polarization filter on the right; and a filter trigger for rotating and driving the circular polarization filter module according to timing timing of left and right image emissions from the projector.

Also in this embodiment, the stereoscopic image projection system may further include a synchronizer for acquiring timing synchronization of the left and right images of the projector and providing timing synchronization to the filter driver and a frame for fixing and adjusting the settings. positions of the projector and the circular polarization filter module.

The frame can control the positions of the projector and circular polarization filter module to control two-dimensional (2D) or three-dimensional (3D) image projection. Preferably, the circular polarization filter module further includes a light protection region at a boundary between the left image polarization filter and the right image polarization filter.

In addition, by rotating the circular polarization filter module, the circular polarization filter module can be controlled such that the left image polarization filter is located in a projector emission aperture when the projector emits images at left and the image polarization filter on the right is located in the projector's emission aperture when the projector outputs images on the right.

Another embodiment of the invention provides a stereoscopic image projection system including a stereoscopic image projector system for allowing left and right images according to a polarization method; a screen on which the left and right images are projected; and polarizing glasses through which left and right images selectively pass, the stereoscopic image projector system including a projector to sequentially output left and right images; a circular polarization filter module including a left image polarization filter and a right image polarization filter; and a filter trigger for rotating and driving the circular polarization filter module according to timing timing of left and right image emissions from the projector.

ADVANTABLE EFFECTS

According to the embodiments of the invention, the system uses only one projector to increase its use in a movie theater or similar and to reduce installation costs and can project stereoscopic images with a high left and right image matching and a wide viewing angle while reducing interference compared to the LCD-shutter-based system.

In addition, the position of the circular polarization filter module is changed using the frame not only to allow 3D image projection, but also to allow general 2D image projection and the Iuz protection region is inserted between the image filters at left and right of the circular polarization filter module, thereby further reducing interference.

Additionally, the sensor is used to efficiently detect the rotational position of the circular polarization filter module at times when the left and right images are switched. In particular, the position of the sensor is adjusted by considering image sizes, thereby further enhancing the quality of the stereoscopic image.

Furthermore, it is easy to use the stereoscopic image projector system according to the embodiments of the invention as it is easily installed in front of the existing projector.

DESCRIPTION OF DRAWINGS

The accompanying drawings, which are included to provide a further understanding of the invention, illustrate embodiments of the invention and together with the description serve to explain the principle of the invention.

In the drawings:

Figure 1 illustrates the structure of a conventional dual projector system for

stereoscopic image projection;

Figure 2 illustrates the structure of a conventional stereoscopic image projection system based on a method of dividing the area of an LCD module;

Figure 3 illustrates the structure of a conventional LCD 20 shutter-based system for stereoscopic image projection;

Figure 4 illustrates the structure of a stereoscopic image projector system used in a single projector circular filter type system according to one embodiment of the invention;

Figure 5 illustrates a preferable structure of a circular polarization filter module used in a single projector circular polarization filter type system according to one embodiment of the invention;

Figure 6 illustrates the operation and position of a sensor used for a circular polarization filter module according to a preferred embodiment of the invention;

Figure 7 is a drawing for explaining in detail a method for determining the position of a sensor used in a circular polarization filter module by considering image sizes in accordance with a preferred embodiment of the invention;

Figure 8 illustrates a structure for efficiently determining an image size and sensor position based on image size according to a preferred embodiment of the invention;

Figure 9 illustrates comparisons of interference extensions occurring between

left and right images according to the conventional LCD shutter method and according to the single projector circular polarization filter methods of the embodiments of the invention; and

Figure 10 illustrates an overall structure of a single projector circular polarization filter type stereoscopic image projection system in accordance with one embodiment of the invention.

5 MODE OF INVENTION

Reference will now be made in detail to preferred embodiments of the present invention with reference to the accompanying drawings. The detailed description, which will be provided below with reference to the accompanying drawings, is intended to explain exemplary embodiments of the present invention, rather than to show the only embodiments that may be implemented in accordance with the invention.

The following detailed description includes specific details to provide a complete understanding of the present invention. However, it will be apparent to those skilled in the art that the present invention may be practiced without such specific details. In some cases, known structures and devices are omitted or shown in block diagram form, focusing on important features of the structures and devices so as not to obscure the concept of the present invention. The same reference numbers will be used throughout this descriptive report to refer to the same or similar parts.

The present invention suggests that a method of sequentially omitting left and right images is used to allow single-projector stereoscopic image projection and a circular polarization filter module to be used to polarize images left and right differently. right. Using the circular polarization filter module to polarize images left and right can reduce the interference problem with the LCD shutter method. Use polarization filter

Circular 25 also has an advantage in that it can increase the viewing angle of stereoscopic images compared to when linear polarization filters are used.

Figure 4 illustrates the structure of a stereoscopic image projector system used in a single projector circular filter type system according to one embodiment of the invention.

As shown in Figure 4, the stereoscopic image projector system according to the embodiment of the invention includes a single projector 401, a circular polarization filter module 402, and a filter driver 406. The projector 401 sequentially outputs images to the left. It's on the right. The circular polarization filter module 35 402 includes a left image polarization filter and a right image polarization filter. The filter driver 403 rotates and drives the circular polarization filter module 402 according to the timing of the left image and right image emission timing of the projector 401. The stereoscopic image projector system may further include a synchronizer 404 for acquiring left and right image timing timing synchronization of the projector 401 and transferring the timing synchronization to filter driver 403 5 as shown in Figure 4. Reference will now be made to the detailed operations. of the stereoscopic image projector system.

First, the projector 401 receives stereoscopic image content, including images on the left and images on the right, sequentially (or alternately) stored in the stereoscopic image content, and continuously outputs the content.

This indicates that a conventional projector for projecting 2D images can be used directly as projector 401. That is, projector 401 sequentially outputs images on the left and images on the right according to the information of the received stereoscopic image content.

By rotating the circular polarization filter module 402 which includes a

left image polarization filter and a right image polarization filter as described above, the circular polarization filter module 402 is controlled such that the left image polarization filter is located in an emission aperture of the 401 when the 401 projector emits images on the left and the image bias filter on the right is located in the emitting aperture of the projector.

2 0 projector 401 at the moment when projector 401 outputs images on the right. To accomplish this, the synchronizer 404 must be able to acquire the switching timing between the left and right images in the stereoscopic image content input to the projector 401. The synchronizer 404 controls the filter trigger 403 to adjust the trigger timing of the projector. circular polarization filter module 402 according to

2 5 the timing information acquired. Timing synchronization can be

set to detect a synchronization signal containing timing synchronization information from a High Definition Serial Digital Interface (HD-SDI) port for transmitting stereoscopic image content, a GPIO port, or any other corresponding port.

The stereoscopic image projector system may also include a frame (not

shown) to fix and adjust the positions of the projector 401 and circular polarization filter module 402. The frame can control the position of the projector 401 and / or circular polarization filter module 402 to control 2D or 3D image projection. . For example, in case of 2D image projection, the frame lowers the position of the filter module.

35 of circular polarization 402 to control the images emitted by the projector 401 so as to

do not pass through the circular polarization filter module 402.

As a conventional projector can be used directly as the projector 401 in the stereoscopic image projector system described above, the circular polarization filter module 402 and filter driver 403, preferably in conjunction with synchronizer 404 and / or frame ( not shown) may constitute apparatus for stereoscopic image projector systems according to another embodiment of the invention. This apparatus for stereoscopic image projection systems can easily be mounted on the front side of an existing projector. Thus, the apparatus for stereoscopic image projection systems can be compatible with a variety of projectors.

The following is a description of a preferred structure of the circular polarization filter module 402.

Figure 5 illustrates a preferred structure of the circular polarization filter module used in the single projector circular polarization filter type system according to one embodiment of the invention.

As shown in Figure 5, the circular polarization filter module 402 according to the embodiment of the invention includes a left image polarization filter for left image polarization (denoted by "L" in Figure 5) and a filter from right image polarization to right image polarization (denoted by "R" in Figure 5) and preferably further includes a protection region of Iuz 402a.

Generally, the circular polarization filter includes a linear polarization filter and a quarter phase difference plate to convert the incident light to right or left circularly polarized light. Stereoscopic display using circular polarization filters has an advantage over those using linear polarization filters in which the viewer can see projected 3D images even when they significantly tilt their heads left or right as described above. However, stereoscopic displays using circular polarization filters also have a problem where color interference from the left and right images of stereoscopic scenes easily occurs.

Thus, the light protection region 402a is inserted as shown in Figure 5 to reduce interference between the left and right images emitted by the projector at the time when the left and right images are switched. To accomplish this, it is preferable that the Iuz 402a protection region be located at the projector's emission aperture at the moment when the images to the left and right of the projector are switched.

Although Figure 5 shows that a circular polarization filter module 402 includes a left image filter L and a right image filter R, circular polarization filter module 420 may include a plurality of left and right image filters. a plurality of image filters on the right. For example, when the circular polarization filter module includes two left image filters and two right image filters, the speed at which the filter driver triggers the circular polarization filter module may be reduced to half that of the case. of Figure 5.

It is preferable that each filter is in the form of a fan with a decreasing center angle in the center of the circular polarization filter module as the number of left image filters and the right image filter number increases as in the above embodiment. . If the center angles of the left image filter L and the right image filter R are large, the stereoscopic image quality may be reduced due to the mismatch between the polarization angles of the circular polarization filter module and polarization glasses when you rotate the circular polarization filter module. Accordingly, a preferred embodiment of the invention suggests that the circular polarization filter module include an appropriate number of left image polarization filters L, and right image polarization filters R, of the same fan shape to reduce the center angle, thereby minimizing the reduction in stereoscopic image quality due to mismatched polarization angles.

One method of increasing the numbers of the left image polarization filters L1 right image polarization filters R is to repeatedly arrange the left image polarization filters L, and the right image polarization filters R, alternately, for example, in the order of L, R, L, R, and another method is to repeat the same-side image filters and then repeat the opposite-side image filters, for example, in the order of L , L, L,, R, R, R,, R. By repeating the left image filters L, and the right image filters R, this may also prevent the reduction of stereoscopic image quality due to mismatch between the polarization angles of the circular polarization filter module and the

2 5 polarization. Although any number of left or right image filters can be

To be repeated, it is preferable that the left image filter region L is divided into six equal sections and the right image filter region R is divided into six equal sections considering the flicker due to the interval between each filter section in the module. of circular polarization filter. The present invention is not necessarily limited to that

3 0 example and can define any appropriate number of filter sections that reasonably

balance the polarization mismatch problem with the flicker problem.

In one embodiment of the invention, the circular polarization filter module may further include a sensor for detecting whether or not the left image polarization filter is located in the projector emission aperture at the moment when the projector emits left images and The right image bias filter is or is not located in the projector's emission aperture at the moment when the projector outputs the images on the right. The concept of this sensor for the circular polarization filter module will now be described in more detail with reference to the drawings.

Figure 6 illustrates the operation and position of a sensor used for a circular polarization filter module according to a preferred embodiment of the invention.

In Figure 6, it is assumed that the projector outputs an image 601a at switching time from left to right (L-> R) images. The circular bias filter module 402 may be adjusted to rotate such that its region located in the projector's emission aperture is switched from the left image bias filter region L to the image bias filter region right R at the moment when the image is switched from the left images to the right images. In the case of such adjustment of the circular polarization filter module 402, the sensor may adjust to detect whether or not the boundary between the left and right polarization regions of the circular polarization filter module 402 is located at a position as shown in Figure 6 at this time.

However, as can be seen from Figure 6, if the boundary between the left and right polarization regions of the circular polarization filter module 402 'is located at a position aa shown in Figure 6 at the time when image 601a emitted by the projector is switched from images on the left to images on the right, the circular polarization filter module 402 cannot properly polarize an image on the right for a duration during which the projector outputs the image on the right. That is, additional interference could occur if the position of the boundary between the left and right bias regions of the circular bias filter module 402 in the timing of switching between left and right images is adjusted without regard to image size. 601a.

Thus, a preferred embodiment of the invention suggests that the circular polarization filter limit position in the timing of switching between left and right images be adjusted considering the size of the images. Specifically, in the above example, the boundary between the left and right bias regions of the circular bias filter module 402 may be adjusted to be located at a position bb rather than at the position aa shown in Figure 6 at moment when the image 601a emitted by the projector is switched from the images on the left to the images on the right. This embodiment also suggests that sensor 402b for detecting the rotational position of the circular polarization filter module 402 is adjusted to be located at position b or b. This adjustment of sensor position 402b may prevent interference caused over a period of time corresponding to image size 601a.

Although it is assumed, in the example of Figure 6, that the images are of a uniform size, the images may have various sizes according to the projector type, or the like, as described below.

Figure 7 is a drawing to explain in detail a method for determining the position of a sensor used in a circular polarization filter module by considering image sizes in accordance with a preferred embodiment of the invention.

Specifically, Figure 7 illustrates that the projector can output multiple images such as an image 601a, an image 601b, and an image 601c. Adjusting the boundary position between the left image polarization filter region L, and a right image polarization filter region R, of a circular polarization filter module 402 at the moment when images are switched from From images on the left to images on the right, can be changed according to the size of the images. It is preferable that the position of a sensor 402b is also adjusted according to the changed limit position. For example, it is preferable in Figure 7 that the sensor be located in a position b or b when the image 601a is issued, that the sensor is located in a position c or c when the image 601b is emitted, and that the sensor is located at a position d or d when image 601c is output. A preferred embodiment of the invention suggests that the position of the sensor be adjusted according to various image sizes in this manner.

Figure 8 illustrates a structure for efficiently determining an image size and sensor position based on image size according to a preferred embodiment of the invention.

As described above with reference to Figure 7, it is preferable that when the size of the images is changed, the position of the sensor is adjusted according to the changed image size. However, when the position of a sensor is roughly adjusted on a projector used in cinemas, the adjusted position may be incorrect, thereby reducing the quality of the stereoscopic image.

Accordingly, a more preferred embodiment of the invention suggests that a circular polarization filter module 402 additionally includes measuring means 801 for measuring the size of an image and position determining means 802 for determining the position of a sensor 402b according to the invention. measuring means 801 as shown in Figure 8. Specifically, in the example of Figure 8, if image sizes 0,

1, 2, 3, 4, 5 are measured by the measuring means, sensor 402b may be located at positions 0, 1, 2, 3, 4, 5, corresponding to the measured image sizes, respectively.

Although Figure 8 shows a method in which the image size and corresponding sensor position are quantitatively adjusted using a scale type to illustrate the preferred embodiment of the invention, any means for determining image size and corresponding sensor position can be adjusted. be used as the means of measurement and as the means of determining position in the invention.

The above methods according to the embodiments of the invention will now be described in comparison to the conventional LCD shutter method.

Figure 9 illustrates comparisons of the extent of interference occurring between the left and right images according to the conventional LCD shutter method and the single projector circular polarization filter methods of the embodiments of the invention.

Left and Right at the top of Figure 9 denote time intervals during which the projector outputs left and right images respectively. It can be seen from Figure 9 that when left and right images are emitted alternately in this manner, relatively large interference occurs in the switching timings between left and right images if each image is polarized using the LCD shutter as shown. shown in Figure 3. Generally, the LCD shutter responds more slowly during trim times than during lift times. In the example in Figure 9, the images on the left are projected during LCD lift cycles and the images on the right are projected during trim cycles so that the most interference occurs in the timing of switching images from the left to the images on the right of the LCD. than in switching timings from the right images to the left images. Images other than those shown in Figure 9 may also be projected during cycles. On the other hand, as shown in Figure 9, almost no interference occurs in the switching timings between the left and right images if the circular polarization filter module according to the embodiment of the invention is used. Adjusting the Iuz protection region as shown in Figure 5 may further reduce the possibility of interference occurring.

As shown in Figure 9, in the case of the method using the LCD shutter, interference occurring in cycles during which images on the left are omitted, and cycles during which images on the right are emitted; except switching cycles; It is also larger than in the case of the method using the circular polarization filter module according to the embodiment of the invention since the LCD shutter method has a lower polarization ratio of images to one left or right side than the other. circular polarization method according to the invention.

Accordingly, by using the single projector according to the invention, it is possible to maximize the projector's use in movie theater or similar projection rooms and to reduce installation costs for stereoscopic image projection and also to reduce interference between images on the left. and on the right, compared to the conventional LCD shutter method, thereby performing more excellent stereoscopic images.

The following table shows comparisons of the stereoscopic image projection system using the single projector circular polarization filter module according to the above embodiments of the invention with other systems.

Classification Advantages Problems DUAL PROJECTOR Polarization filter Easy construction in low use in short time linear. movie theater. Increase Implementation of the cost of quality installation of the stereoscopic projector. Excellent problem of matching left and right images. Limited viewing angle. Polarization filter Easy construction in low use in short time running. movie theater. Increase Implementation of quality costs installation of the stereoscopic projector. Excellent problem. Matching Enhanced left and right angle images. visualization. UNIQUE PROJECTOR LCD Shutter Improvement in the event of interference use. movie theater. Quality Improvement in stereoscopic plus low match. left and right images. Improvement in viewing angle. Polarization filter Improvement in Circular use for cinema use. interference in Enhancement compared to dual left image projector method matching. It's on the right. Viewing angle improvement. Reduction in interference occurrence. As shown in Table 1, the circular polarization filter method according to the invention overcomes the problem of use in movie theater screenings and the problem of matching left and right images in the single projector method 5 and overcomes The limited viewing angle problem in the method using linear polarization filters also significantly reduces the interference problem that occurs seriously in the LCD shutter method.

Although the circular polarization filter method according to the invention has an interference possibility problem as opposed to the dual projector method since circular polarization filters are used, their interference problem is much less serious than that in the LCD shutter method and the interference problem can be overcome to some extent by adjusting the Iuz protection region between the left and right image filters as shown in Figure 5.

Figure 10 illustrates an overall structure of a single projector circular polarization filter type stereoscopic image projection system in accordance with one embodiment of the invention.

As shown in Figure 10, the single projector circular polarization filter type stereoscopic image projection system according to the embodiment of the invention includes a stereoscopic image projector system 705, a screen 706, and 20 sunglasses. bias 707 as described above. The 705 stereoscopic image projection system outputs left and right images according to the polarization method. The left and right images are projected on screen 705. The left and right images selectively pass through the 707 polarizing glasses.

Stereoscopic image projection system 705 is characterized by including a single projector 701, a circular polarization filter module 702, and a filter driver 703 as described above. The single projector 701 sequentially outputs left and right images. The circular polarization filter module 702 includes a left image polarization filter and a right image polarization filter. The filter driver 703 rotates and drives the circular polarization filter module 702 according to the left and right image timing synchronization of the projector. Consequently, with just one projector, it is possible to project stereoscopic images with high left and right image matching and a wide viewing angle, significantly reducing interference compared to the LCD shutter method.

Detailed description of preferred embodiments of the present invention has been provided to enable those skilled in the art to implement and practice the invention. While the invention has been described with reference to preferred embodiments, those skilled in the art will appreciate that various modifications and variations may be made to the present invention without departing from the spirit or scope of the invention described in the appended claims. Accordingly, the invention should not be limited to the specific embodiments described herein, but should be granted the broadest scope consistent with the novel principles and characteristics disclosed herein.

INDUSTRIAL APPLICABILITY

The stereoscopic image projection system using the circular polarization filter module according to the invention increases its use in conference rooms.

20 The projection of a cinema or the like reduces installation costs as it uses only one projector and can also project stereoscopic images with high left and right image matching and a wide viewing angle while reducing interference compared with the LCD shutter method. Thus, the stereoscopic image projection system according to the invention is

2 5 suitable for use as a system for stereoscopic image projection in theaters.

The stereoscopic image projection system according to the invention may not only be used in its entirety, but a stereoscopic image projection system including a projector, a circular polarization filter module, and a filter driver included in the Stereoscopic image projection system, can also be used alone. In addition, as a conventional projector can be used directly for the stereoscopic image projection system, the circular polarization filter module and filter driver can be used as standalone devices for the stereoscopic image projection system.

Claims (19)

1. (Spliced) Stereoscopic image projector system using a polarization method, the stereoscopic image projector system is characterized by: a projector for sequentially outputting left and right images; a circular polarization filter module including a left image polarization filter and a right image polarization filter; and a filter driver for driving the circular polarization filter module in accordance with the timing timing of the left and right image emissions of the projector such that the left image polarization filter is located in an aperture of projector output when the projector outputs images on the left and the right image bias filter is located in the projector emission aperture when the projector outputs images on the right by rotating the circular polarization filter module, where the filter module The circular polarization filter also includes a light protection region at a boundary between the left image polarization filter and the right image polarization filter. Stereoscopic image projector system according to claim 1, characterized in that it further comprises a synchronizer for acquiring timing synchronization of the left and right image emissions of the projector and providing timing synchronization to the filter driver. (Spliced) Stereoscopic image projector system according to claim 1, further comprising a frame for securing and adjusting the positions of the projector and the circular polarization filter module. Stereoscopic image projector system according to claim 3, characterized in that the frame controls the positions of the projector and the circular polarization filter module to control whether the stereoscopic image projector system should project an image. two-dimensional (2D) or a three-dimensional (3D) image. 5. (Canceled) 6. (Amended) Stereoscopic image projector system according to claim 1, characterized in that the projector receives the stereoscopic image content sequentially, including the left and right images, and sequentially outputs the left images. and to the right of the content. 7. (Canceled) 8. (Spliced) Stereoscopic image projector system according to claim 1, characterized in that the circular polarization filter module further includes a sensor for detecting whether or not the left polarization image filter is located. at the projector's emission aperture when the projector outputs images on the left, and whether or not the image polarization filter on the right is located at the projector's emission aperture when the projector outputs images on the right. (Spliced) Stereoscopic image projector system according to claim 8, characterized in that a sensor position is determined by considering a size of one image on the left and one image on the right; emitted by the projector. Stereoscopic image projector system according to claim 9, characterized in that the circular polarization filter module further includes: measuring means for measuring the size of the left and right images emitted by the projector; and position determination means for determining the position of the sensor according to the measurement medium measurement. (Spliced) Stereoscopic image projector system according to claim 1, characterized in that the circular polarization filter module includes a plurality of left polarization image filters and a plurality of polarization polarization filters. image on the right. (Spliced) Stereoscopic image projector system according to claim 11, characterized in that each of the plurality of left-hand image polarization filters and right-hand image polarization filters has a reduced central angle. as the number of image filters on the left and image filters on the right increases. 13. (Spliced) Apparatus for a single projector-type stereoscopic image projection system sequentially outputting left and right images, the apparatus is characterized by: a circular polarization filter module including a left image polarization filter and a right image polarization filter; and a filter driver for driving the circular polarization filter module in accordance with the timing timing of the left and right image emissions of the projector such that the left image polarization filter is located in an aperture of projector output when the projector outputs images on the left and the right image bias filter is located in the projector emission aperture when the projector outputs images on the right by rotating the circular polarization filter module, where the filter module The circular polarization filter also includes a light protection region at a boundary between the left image polarization filter and the right image polarization filter. Apparatus according to claim 13, characterized in that it further comprises a synchronizer for acquiring timing synchronization of the left and right images of the projector and providing timing synchronization to the filter driver. (Spliced) Apparatus according to claim 13, further comprising a frame for securing and adjusting the positions of the projector and circular polarization filter module. 16. (Spliced) Apparatus according to claim 15, characterized in that the frame controls the positions of the projector and the circular polarization filter module to control whether the stereoscopic image projector system should project a two-dimensional image ( 2D) or a three-dimensional (3D) image. 17. (Canceled) 18. (Canceled) 19. (Spliced) Stereoscopic image projection system Characterized by comprising: a stereoscopic image projector system for emitting left and right images according to a polarization method; a screen on which the left and right images are projected; and polarizing glasses through which the left and right images selectively pass, wherein the stereoscopic image projector system comprises: a projector for sequentially emitting left and right images; a circular polarization filter module including a left image polarization filter and a right image polarization filter; and a filter driver for driving the circular polarization filter module in accordance with the timing timing of the left and right image emissions of the projector such that the left image polarization filter is located in an aperture of projector output when the projector outputs images on the left and the right image bias filter is located in the projector emission aperture when the projector outputs images on the right by rotating the circular polarization filter module, where the filter module The circular polarization filter also includes a light protection region at a boundary between the left image polarization filter and the right image polarization filter.